Adjustment of measurement errors to reconcile precipitation distribution in the high‐altitude Indus basin

Dahri, Zakir Hussain; Moors, E.J.; Ludwig, Fulco; Ahmad, Shakil; Khan, Asif; Ali, Irfan; Kabat, P.

doi:10.1002/joc.5539

Cited by 61 publications

(76 citation statements)

References 72 publications

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“…Several climate studies of the Indus have focused on using lower-elevation precipitation gauges, which are then used to spatially interpolate basin-wide precipitation. Dahri et al (2016) and Dahri et al (2018) have assembled perhaps the largest collection of climatological measurements covering the AKAH region, mostly based on gauge measurements, as part of a study on the hydrometeorology of the Indus Basin. Using undercatch corrections based on wind, often from reanalysis, they increased precipitation estimates by 21 % on average throughout the Indus Basin (Dahri et al, 2018).…”

Section: Literature Reviewmentioning

confidence: 99%

“…Dahri et al (2016) and Dahri et al (2018) have assembled perhaps the largest collection of climatological measurements covering the AKAH region, mostly based on gauge measurements, as part of a study on the hydrometeorology of the Indus Basin. Using undercatch corrections based on wind, often from reanalysis, they increased precipitation estimates by 21 % on average throughout the Indus Basin (Dahri et al, 2018). For example, in the Gilgit sub-basin, they find an unadjusted precipitation estimate of 582 mm yr −1 , adjusted to 787 mm yr −1 , a 35 % increase.…”

Section: Literature Reviewmentioning

confidence: 99%

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Comparison of modeled snow properties in Afghanistan, Pakistan, and Tajikistan

et al. 2020

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Ice and snowmelt feed the Indus River and Amu Darya in western High Mountain Asia, yet there are limited in situ measurements of these resources. Previous work in the region has shown promise using snow water equivalent (SWE) reconstruction, which requires no in situ measurements, but validation has been a problem. However, recently we were provided with daily manual snow depth measurements from Afghanistan, Tajikistan, and Pakistan by the Aga Khan Agency for Habitat (AKAH). To validate SWE reconstruction, at each station, accumulated precipitation and SWE were derived from snow depth using the numerical snow cover model SNOWPACK. High-resolution (500 m) reconstructed SWE estimates from the Parallel Energy Balance Model (ParBal) were then compared to the modeled SWE at the stations. The Alpine3D model was then used to create spatial estimates at 25 km resolution to compare with estimates from other snow models. Additionally, the coupled SNOWPACK and Alpine3D system has the advantage of simulating snow profiles, which provides stability information. The median number of critical layers and percentage of faceted layers across all of the pixels containing the AKAH stations were computed. For SWE at the point scale, the reconstructed estimates showed a bias of − 42 mm (−19 %) at peak SWE. For the coarser spatial SWE estimates, the various models showed a wide range, with reconstruction being on the lower end. A heavily faceted snowpack was observed in both years, but 2018, a dry year, according to most of the models, showed more critical layers that persisted for a longer period.

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Section: Literature Reviewmentioning

confidence: 99%

Section: Literature Reviewmentioning

confidence: 99%

Comparison of modeled snow properties in Afghanistan, Pakistan, and Tajikistan

et al. 2020

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“…Therefore, a comprehensive evaluation of the basin-wide water cycle is needed. Studies that have addressed this issue have stressed the uncertainties inherent in the observed precipitation (Singh et al, 2011;Gardelle et al, 2012;Immerzeel et al, 2015;Wang et al, 2017;Dahri et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

“…Beside the risk of corruption or missing values in the reporting process, it has been demonstrated that rain gauges can underestimate precipitation (Sevruk, 1984;Goodison et al, 1989). The main source of underestimation is the wind-driven under-catchment that can reach up to 50 % during snowfall (Goodison et al, 1989;Adam and Lettenmaier, 2003;Wolff et al, 2015;Dahri et al, 2018), but also includes the wetting of the instrument, evaporation before measuring, and splashing out (WMO, 2008). Dahri et al (2018) used the guidelines from the World Meteorological Organization (WMO) to re-evaluate the precipitation measured from hundreds of rain gauges in the upper Indus and found the underestimation to be between 1 % and 65 % for each station, and 21 % across the basin.…”

Section: Introductionmentioning

confidence: 99%

“…Rain gauges are not only scarce in mountainous areas, but their location is also biased. In order to be accessible all year long, they are gener-ally situated at the bottom of valleys, and these locations appear to be significantly drier than locations at altitude (Archer and Fowler, 2004;Ménégoz et al, 2013;Immerzeel et al, 2015;Dahri et al, 2018), which means that the interpolation method underestimates precipitation in the surrounding mountains.…”

Section: Introductionmentioning

confidence: 99%

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Cross-validating precipitation datasets in the Indus River basin

Baudouin

Herzog

Petrie

2020

Hydrol. Earth Syst. Sci.

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Abstract. Large uncertainty remains about the amount of precipitation falling in the Indus River basin, particularly in the more mountainous northern part. While rain gauge measurements are often considered as a reference, they provide information for specific, often sparse, locations (point observations) and are subject to underestimation, particularly in mountain areas. Satellite observations and reanalysis data can improve our knowledge but validating their results is often difficult. In this study, we offer a cross-validation of 20 gridded datasets based on rain gauge, satellite, and reanalysis data, including the most recent and less studied APHRODITE-2, MERRA2, and ERA5. This original approach to cross-validation alternatively uses each dataset as a reference and interprets the result according to their dependency on the reference. Most interestingly, we found that reanalyses represent the daily variability of precipitation as well as any observational datasets, particularly in winter. Therefore, we suggest that reanalyses offer better estimates than non-corrected rain-gauge-based datasets where underestimation is problematic. Specifically, ERA5 is the reanalysis that offers estimates of precipitation closest to observations, in terms of amounts, seasonality, and variability, from daily to multi-annual scale. By contrast, satellite observations bring limited improvement at the basin scale. For the rain-gauge-based datasets, APHRODITE has the finest temporal representation of the precipitation variability, yet it importantly underestimates the actual amount. GPCC products are the only datasets that include a correction factor of the rain gauge measurements, but this factor likely remains too small. These findings highlight the need for a systematic characterisation of the underestimation of rain gauge measurements.

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